Interactive imaging systems and methods for motion control by users

ABSTRACT

In various embodiments, the present invention provides a system and associated methods of calibration and use for an interactive imaging environment based on the optimization of parameters used in various segmentation algorithm techniques. These methods address the challenge of automatically calibrating an interactive imaging system, so that it is capable of aligning human body motion, or the like, to a visual display. As such the present invention provides a system and method of automatically and rapidly aligning the motion of an object to a visual display.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the benefit of priority of U.S. ProvisionalApplication No. 60/875,667 filed Dec. 19, 2006 and entitled “SYSTEM ANDASSOCIATED METHODS OF CALIBRATION AND USE FOR AN INTERACTIVE IMAGINGENVIRONMENT” the contents of which are incorporated in full by referenceherein.

FIELD OF THE INVENTION

The present invention relates generally to the fields of interactiveimaging and interactive imaging system calibration. More specifically,the present invention relates to an auto-calibrating interactive imagingsystem and a method by which the interactive imaging system isinitialized and automatically calibrated by optimizing the parameters ofa segmentation algorithm using an objective function.

BACKGROUND OF THE INVENTION

An interactive imaging experience includes an environment in which aninteractive display is affected by the motion of human bodies, objects,or the like. A camera, or set of cameras, detects a number of featuresof the human bodies before the camera, such as their silhouettes, hands,head, and direction of motion, and determines how these featuresgeometrically or photometrically relate to the visual display. Forexample, a user interacting before a front-projected display casts ashadow on an optional display medium such as a projection screen, or thelike. The interactive imaging system is capable of aligning the camera'sdetection of the silhouette of the human body with the shadow of thehuman body. This geometric or photometric alignment creates a naturalmapping for controlling elements in the visual display. Persons of allages can likely recall an experience of playing with their shadows andcan thus understand that their motion in front of a source of brightlight will produce a shadow whose motion behaves exactly as expected.This experience is capitalized upon in an interactive imagingexperience.

In order for interactive imaging systems to operate and functionproperly, such systems must be accurately calibrated and optimizedfirst. Procedures exist under which the motion of the human body, or thelike, is geometrically or photometrically aligned to the actual visualdisplay, creating a natural mapping for use in an interactive imagingsystem. However, these interactive imaging devices and systems requirean extensive period of time, often taking many hours, for calibrationand initialization. Such a delay results in long periods of wait timewith no use of the interactive imaging system upon setup, until suchtime the calibration period is completed. This is equivalent to poweringon a personal computer, expecting to use it immediately, yet waiting forhours before actual use can begin. Thus, such methods of calibration inan interactive imaging system are not automatic and nearlyinstantaneous, as is desired.

Calibration in an interactive imaging system refers to theinitialization and setting of various setup parameter values. Theseparameter values, once initialized, are used in various segmentationalgorithms. Segmentation, generally, has to do with image processing.Segmentation is a technique concerned with splitting up an image, orvisual display, into segments or regions, each segment or region holdingproperties distinct from the areas adjacent to it. This is often doneusing a binary mask, representing the presence of a foreground object infront of the visual display surface.

A conceptual example of this definition of segmentation is the imageformed on an all-white front-projected visual display when a person, orthe like, is placed in front of the visual display and casts a shadowupon it. In this example, only the black or shadowed region of thevisual display, as viewed on a wall, projection screen, or the like,denotes the presence of a foreground element, a body or similar object,and the white color in the visual display denotes background ornon-presence of a foreground object. Normally, however, thissegmentation is a binary image representation that is computed using amonochrome camera input.

There are a number of segmentation techniques, or algorithms, which arealready well-known in the art. Two of these segmentation techniquesinclude background subtraction and stereo disparity-based foregrounddetection, both of which may be employed for generating a segmentationimage.

All of these algorithms share the need to set parameters which affectthe quality of the segmentation as defined by its similarity to groundtruth and as defined by its speed of execution. Calibration is theprocess of setting these parameters in order to achieve high quality ina visual display while operating at an acceptable execution speed.Unfortunately, existing calibration methods in interactive imagingsystems require too much time for actual calibration and optimization.Such time requirements produce unsuitable delays.

A common approach for generating segmentation images from a camera thatfaces a visual display is to filter the camera to observe onlynear-infrared light while ensuring that the display only emits visible,non-infrared light. By separating the sensing spectrum from the displayspectrum, the problem is reduced from detecting foreground elements in adynamic environment created by a changing display to the problem ofdetecting foreground elements in a static environment, similar tochroma-key compositing systems with green or blue screens.

Background subtraction is the most popular means of detecting foregroundelements (segmentation) for real-time computer vision applications. Amodel of the background, B, is maintained over time and is usuallyrepresented as an image with no foreground elements. It is assumed thatthe camera can view the entire area covered by the visual display;however, it is not assumed that the boundaries of the camera alignexactly with the boundaries of the visual display. Therefore, any imagecaptured by the camera, including the background model, must be warpedsuch that the boundaries of the visual display and warped image doalign. Warping is performed by defining four coordinates in the cameraimage C₁, C₂, C₃, and C₄, and bilinearly interpolating the pixel valuesthat are enclosed by a quadrilateral whose corners are defined by C₁,C₂, C₃, and C₄, As a result, the warped camera geometrically correspondsto the display. A method for automatically computing these coordinatesin the camera using homographies was presented in R. Sukthankar, R.Stockton, M. Mullin. Smarter Presentations: Exploiting Homography inCamera-Projector Systems. Proceedings of International Conference onComputer Vision, 2001. (A homography is a 2D perspective transformation,represented by a 3×3 matrix that maps each pixel on a plane such as acamera's image plane to another plane, such as a projector's imageplane, through an intermediate plane, such as the display surface.) Thismethod, however, assumes that the display may be viewed by the cameraand the camera whose image needs to be warped is infrared-pass filtered,therefore eliminating the visibility of the display. Additionally, anautomatic camera-camera homography estimation method was disclosed by M.Brown and D. G. Lowe in Recognising Panoramas. In Proceedings of the 9thInternational Conference on Computer Vision (ICCV2003), pages 1218-1225,Nice, France, October 2003.

While these patents and other previous systems and methods haveattempted to solve the above mentioned problems, none have provided anauto-calibrating interactive imaging system and a method by which theinteractive imaging system is initialized and automatically calibratedby optimizing the parameters of a segmentation algorithm using anobjective function. Thus, a need exists for a system and methods ofcalibration and use in an interactive imaging system in which thecalibration of parameters for segmentation algorithms is completed at anacceptable execution speed, and in which there is no deterioration inthe quality of the visual display images.

BRIEF SUMMARY OF THE INVENTION

In various embodiments, the present invention provides a system andmethods of calibration and use for an interactive imaging environmentbased on various segmentation techniques. This system and associatedmethods address the challenge of automatically calibrating aninteractive imaging system, so that it is capable of aligning human bodymotion, or the like, to a visual display. Although this disclosuredetails two segmentation algorithms that operate using specific hardwareconfigurations, the disclosed calibration procedure, however, is generalenough for use with other hardware configurations and segmentationalgorithms.

The present invention addresses the challenge of automaticallycalibrating and optimizing an interactive imaging system, so that it iscapable of aligning human body motion, or the like, to a visual display.As such the present invention is capable of automatically and rapidlyaligning the motion of an object to a visual display.

In one exemplary embodiment of the present invention, anauto-calibrating interactive imaging system is disclosed. Theauto-calibrating interactive imaging system includes a central controlunit; an infrared image sensor; a visible image sensor; illuminationenergy devices, or the like, for illuminating the display surface withinfrared light; a display of any kind, under the assumption that thedisplay does not emit infrared light; and, optionally, a display medium.

In another exemplary embodiment of the present invention, a method ofcalibration and use in an interactive imaging system is provided inwhich the parameters for geometric calibration are automaticallydetermined and initialized by optimizing an objective function. Forexample, using the background subtraction segmentation algorithm, theparameters to be optimized are C₁, C₂, C₃, and C₄, the warpingparameters, which are coordinates in a camera image, corresponding tothe corners of the projection.

In another exemplary embodiment of the present invention, a method ofcalibration and use in an interactive imaging system is provided inwhich the parameters for photometric calibration are automaticallydetermined and initialized by optimizing an objective function. Forexample, using the background subtraction segmentation algorithm, theparameters to be optimized are a threshold, t, a median filter kernel,m, the number of median filter operations, n and the camera's exposure,e.

There has thus been outlined, rather broadly, the features of thepresent invention in order that the detailed description that followsmay be better understood, and in order that the present contribution tothe art may be better appreciated. There are additional features of theinvention that will be described and which will form the subject matterof the claims. In this respect, before explaining at least oneembodiment of the invention in detail, it is to be understood that theinvention is not limited in its application to the details ofconstruction and to the arrangements of the components set forth in thefollowing description or illustrated in the drawings. The invention iscapable of other embodiments and of being practiced and carried out invarious ways. Also, it is to be understood that the phraseology andterminology employed are for the purpose of description and should notbe regarded as limiting.

As such, those skilled in the art will appreciate that the conception,upon which this disclosure is based, may readily be utilized as a basisfor the designing of other structures, methods, and systems for carryingout the several purposes of the present invention. It is important,therefore, that the claims be regarded as including such equivalentconstructions insofar as they do not depart from the spirit and scope ofthe present invention.

Additional aspects and advantages of the present invention will beapparent from the following detailed description of an exemplaryembodiment which is illustrated in the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention is illustrated and described herein with referenceto various drawings, in which like reference numerals denote likeapparatus components and/or method steps, and in which:

FIG. 1 is a schematic diagram illustrating the use of geometriccalibration in an interactive imaging environment, particularlyillustrating the projection image, according to an embodiment of thepresent invention.

FIG. 2 is a schematic diagram illustrating the use of geometriccalibration in an interactive imaging environment, particularlyillustrating the visible-pass filtered camera image, according to anembodiment of the present invention.

FIG. 3 is a schematic diagram illustrating the use of geometriccalibration in an interactive imaging environment, particularlyillustrating the infrared-pass filtered camera image, according to anembodiment of the present invention.

FIG. 4 is a schematic diagram illustrating the use of geometriccalibration in an interactive imaging environment, particularlyillustrating the various mapping techniques, according to an embodimentof the present invention.

FIG. 5 is a schematic diagram illustrating the use of photometriccalibration in an interactive imaging environment, particularlyillustrating the visual display goal, according to an embodiment of thepresent invention.

FIG. 6 is a schematic diagram illustrating the use of photometriccalibration in an interactive imaging environment, particularlyillustrating a non-optimized visual display with noise and having a poorvisual quality, according to an embodiment of the present invention.

FIG. 7 is a schematic diagram illustrating the use of photometriccalibration in an interactive imaging environment, particularlyillustrating an optimized visual display with no noise and having a highvisual quality, according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Before describing the disclosed embodiments of the present invention indetail, it is to be understood that the invention is not limited in itsapplication to the details of the particular arrangement shown since theinvention is capable of other embodiments. Also, the terminology usedherein is for the purpose of description and not of limitation.

In one exemplary embodiment of the present invention, a self-calibratinginteractive imaging system 10 includes an image generator 20 operablefor creating or projecting an image. The image generator 20 is, forexample, a visible light projector or the like. Images that may beprojected include, but are not limited to, calibration line-upsilhouettes 60, waves, vapor trails, pool balls, etc. Optionally, theinteractive imaging system 10 also includes a display medium 30 operablefor receiving and displaying the created or projected image. The displaymedium 30 may include a two or three-dimensional projection screen, awall or other flat surface, a television screen, a plasma screen, arear-projection system, a hyper-bright organic light-emitting diode(OLED) surface (possibly sprayed-on as a flexible substrate and onto thesurface of which images are digitally driven), or the like. In general,the interactive imaging system 10 is display agnostic.

The interactive imaging system 10 further includes one or moreillumination energy devices 21 operable for flooding a field of view infront of the created or projected image with illumination energy. Forexample, the one or more illumination energy devices 21 may consist ofone or more infrared lights operable for flooding the field of view infront of the created or projected image with infrared light of awavelength of between about 700 nm and about 10,000 nm. Preferably, theinfrared light consists of near-infrared light of a wavelength ofbetween about 700 nm and about 1,100 nm. Optionally, the infrared lightconsists of structured (patterned) infrared light or structured(patterned) and strobed infrared light, produced via light-emittingdiodes or the like. In an alternative exemplary embodiment of thepresent invention, the image generator 20 and the one or moreillumination energy devices 21 are integrally formed and utilize acommon illumination energy source.

The interactive imaging system 10 still further includes an infraredimage sensor 24 operable for detecting the illumination energy which isin the infrared spectrum. The infrared image sensor 24 is, for example,an infrared-pass filtered camera, or the like. In an alternativeexemplary embodiment of the present invention, the image generator 20and the infrared image sensor 24 are integrally formed. Optionally, anoptical filter is coupled with the infrared image sensor 24 and isoperable for filtering out illumination energy, which is in the infraredspectrum, of a predetermined wavelength or wavelength range, such as,for example, visible light.

The interactive imaging system 10 still further includes a visible lightimage sensor 22 operable for detecting the illumination energy in thevisible light spectrum. The visible light image sensor 22 is, forexample, a visible-pass filtered camera, or the like. In an alternativeexemplary embodiment of the present invention, the image generator 20and the visible light image sensor 22 are integrally formed. In yetanother alternative embodiment, the image generator 20, infrared imagesensor 24, and the visible light image sensor 22 are integrally formed.

The interactive imaging system 10 still further includes a computervision engine 23. The computer vision engine 23 is used to detect acalibration image, or line-up silhouette 60, and an actual body 62 inputfor purposes of calibrating the interactive imaging system 10. Thecomputer vision engine 23 is operable for detecting one or more users,such as an actual body 62, in the field of view in front of the createdor projected image and segmenting the actual body 62 and a background.The computer vision engine 23 gives the interactive imaging system 10“sight” and provides an abstraction of the actual body 62 and thebackground. In this manner, the one or more actual body 62 and thebackground are separated and recognized. When properly implemented, thenumber of actual bodies 62 can be determined, even if there is overlap,and heads and hands may be tracked. Preferably, all of this takes placein real time, i.e. between about 1/60^(th) and 1/130^(th) of a second.Optionally, the computer vision engine 23 is operable for detecting anactual body 62 in the field of view in front of the created or projectedimage and segmenting the one or more actual body 62 and the background.The computer vision engine 23 further provides the control logic forcalibrating the interactive imaging system 10 segmentation algorithms.

The interactive imaging system 10 still further includes a computerinteraction engine 26 operable for inserting an abstraction related tothe one or more actual body 62 and/or the background. The computerinteraction engine 26 understands interactions between the one or moreactual body 62 and/or the background and creates audio/visual signals inresponse to them. In this manner, the computer interaction engine 26connects the computer vision engine 23 and a computer rendering engine27 operable for modifying the created or projected image in response tothe presence and/or motion of the one or more actual body 62, therebyproviding user interaction with the created or projected image in avirtual environment. Again, all of this takes place in real time, i.e.between about 1/60^(th) and 1/130^(th) of a second.

The interactive imaging system 10 still further includes a centralcontrol unit 25 operable for controlling and coordinating the operationof all of the other components of the interactive imaging system 10. Acentral control unit 25 directly connects to the computer interactionengine 26, computer vision engine 23, computer rendering engine 27,visible light image sensor 22, infrared image sensor 24, image generator20, and the illumination energy devices 21.

FIGS. 1 through 4 are illustrative of geometric calibration 12 examplesin an interactive imaging system 10. FIGS. 5 through 7 are illustrativeof photometric calibration 14 examples in an interactive imaging system10.

Referring now to FIG. 1, a schematic diagram illustrating the use ofgeometric calibration 12 in an interactive imaging environment,particularly illustrating the projection image, is shown. A displaymedium 30, such as a projection screen, or the like, is illustrated witha line-up silhouette 60, resembling the outline of a human body,projected onto the display medium 30. As an interactive imaging system10 user stands at a fixed location between the image generator 20 andthe display medium 30, the actual body 62 presence is detected by boththe visible image sensor 22 and the infrared image sensor 24. The onlyinput on the part of the user or operator, represented as an actual body62, is to stand in a fixed location with arms outspread, mimicking theline-up silhouette 60 projected onto the display medium 30. Each of thecorners 32 of the display medium 30 are recognized by the computervision engine 23 and central control unit 25 as P₁, P₂, P₃, and P₄.

Under certain circumstances, the display medium 30 is much larger insize than the actual body 62. For example, consider a twenty-five foottall display medium 30. Although an actual body could stand nearer theimage generator 20 and create a larger shadow, interactive imaging isbetter suited to the actual body that is within three to ten feet awayfrom the display medium. In such an environment, the actual body couldnot cast a shadow large enough to fill the calibration image, theline-up silhouette 60. Fortunately, the central control computer 25 andthe computer vision engine 23 will operate under a relative scale forcalibration purposes. The actual user 62 can initiate the scaling-downprocess by beginning to slowly flap his or her arms up and down untilthe line-up silhouette has downsized (or upsized) to the appropriatescale for line up and calibration purposes.

Referring now to FIG. 2, a schematic diagram illustrating the use ofgeometric calibration 12 in an interactive imaging system 10,particularly illustrating the view as seen by the infrared image sensor24, is shown. The image generator 20, visible image sensor 22, infraredimage sensor 24, and interactive imaging system 10 are displayed. Theinfrared image sensor view 40 illustrates the view as it is seen by theinfrared image sensor 24. The infrared image sensor view 40 shows theouter edges of the camera's viewing range. The features 42 visible inthe infrared image sensor 24, such as the four corners of a screen, inthis example, are shown. The features 42 visible in the infrared imagesensor 24 need not be limited to just the four corners of a screen. Thefeatures 42 may be any four references points, including, but notlimited to, posted notes, black dots, and visible ink. These features 42also alternatively include other training or testing points, under theassumption that the points are located along the same plane, yet not ina linear arrangement. The features 42 visible in the infrared imagesensor 24, are recognized by the central control unit 25 as S₁, S₂, S₃,and S₄.

Referring now to FIG. 3, a schematic diagram illustrating the use ofgeometric calibration 12 in an interactive imaging environment,particularly illustrating the visible-light image sensor view 50, isshown. The image generator 20, visible image sensor 22, infrared imagesensor 24, and interactive imaging system 10 are displayed. Thevisible-light image sensor view 50 illustrates the view as it is seen bythe visible image sensor 22. The visible-pass filtered camera view 50shows the outer edges of the camera's viewing range. The features 52visible in the visible light image sensor 22, such as the four cornersof the display medium 32 in this example, are shown. Each of the corners32 of the display medium 30 are recognized by the central control unit25 as P₁, P₂, P₃, and P₄. Additionally, features 42 visible in theinfrared-pass filtered camera 24 and features 52 visible in thevisible-pass filtered camera 22 allow a mapping to be made from theinfrared image sensor 24 to the visible image sensor 22. This mapping isillustrated as the features 42 visible in the infrared image sensor 24,or S₁, S₂, S₃, and S₄, as recognized by the central control unit 25, areshown in the visible-pass filtered camera view 50.

Referring now to FIG. 4, a schematic diagram illustrating the use ofgeometric calibration 12 in an interactive imaging environment is shown.Each of the views previously illustrating in FIGS. 1 through 3 areshown: the view projected by the image generator 20 to an actual body 62and onto a display medium 30, the infrared image sensor view 40, and thevisible light image sensor view 50. In addition, the interactive imagingsystem 10 is shown. Finally, the mappings 70, 72, 74 of the variousimages are shown to illustrate how geometric calibration 12 is completedin an interactive imaging system 10.

Features visible in the infrared image sensor 42 and features visible inthe visible image sensor 52 allow for a mapping from the infrared imagesensor 24 to the visible image sensor 22. Thus, mapping 1, IR-to-VIZ, 70illustrates an infrared-to-visible homography. The infrared image sensor24 is unable to view the image generator 20; however, the visible imagesensor 22 is able to view the image generator 20. The ability to viewthe image generator 20 in the visible image sensor 22 allows a mappingto be made between the visible image sensor 22 to the image generator20. Thus, mapping 2, VIZ-to-PROJ, 72 illustrates a visible-to-projectorhomography. Mapping, 3 IR-to-PROJ, 74 illustrates the multiplication ofthe results of mapping 2, VIZ-to-PROJ, 72 multiplied against the resultsof the mapping 1, IR-to-VIZ, 70. Mapping 3, IR-to-PROJ, 74 is a mappingfrom the infrared image sensor 24 to the image generator 20. Since theinfrared image sensor 24 is unable to view the image generator 20, thismapping 3, IR-to-PROJ, 74 would not be possible without the use of thevisible image sensor 22, which can see the image generator 20, and theintermediate mappings, Mapping 1, IR-to-VIZ, 70 and Mapping 2,VIZ-to-PROJ, 72.

Referring now to FIG. 5, a schematic diagram illustrating the use ofphotometric calibration 14 in an interactive imaging environment isshown. The image generator 20, visible image sensor 22, infrared imagesensor 24, and interactive imaging system 10 are displayed. Illustratedon the display medium 30 is a line-up silhouette 60 which has beenprojected onto the display medium 30 by the image generator 20. Theline-up silhouette 60 is a calibration image. An actual body 62 (notshown) is to stand before the image generator 20 and try to fit his orher shadow into the displayed line-up silhouette 60. As the actual body62 remains in location, the interactive image system 10 will calibrateitself, initializing the appropriate parameters to use in a givensegmentation algorithm for photometric calibration 14.

Referring now to FIG. 6, a schematic diagram illustrating the use ofphotometric calibration 14 in an interactive imaging environment isshown. This figure illustrates the projected image before photometriccalibration 14 has taken place. The image generator 20, visible imagesensor 22, infrared image sensor 24, and interactive imaging system 10are displayed. No real person or actual body 62 is shown here.Illustrated on the display medium 30 is a line-up silhouette 60 (acalibration image), which has been projected onto the display medium 30by the image generator 20. The noise 80 located sporadically across thedisplay medium 30 illustrates an attempt by the image generator 20, thecentral control unit 25, and the computer vision engine 23 to project asegmented silhouette 64 (shown in FIG. 7). However, the high levels ofnoise 80 and poor visual quality is resultant when optimization of theinteractive imaging system 10 has not occurred. The noise 80 is what thesystem senses as a representation of an actual body 62. FIG. 6illustrates an interactive imaging system 10 that is clearly notcalibrated and optimized.

Referring now to FIG. 7, a schematic diagram illustrating the use ofphotometric calibration 14 in an interactive imaging environment isshown. This figure illustrates the projected image after photometriccalibration 14 has taken place. The image generator 20, visible imagesensor 22, infrared image sensor 24, and interactive imaging system 10are displayed. Shown on the display medium 30 are both line-upsilhouette 60 and the segmented silhouette 64. The line-up silhouette 60has been projected onto the display medium 30 by the image generator 20.An actual body 62 (not shown) is to stand before the image generator 20and try to fit his or her shadow into the displayed line-up silhouette60. As the photometric calibration 14 takes place, the image generator20, central control unit 25, and the computer vision engine 23 calculateand project a segmented silhouette 64 onto the display medium. Thus,after the process of photometric calibration 14, during which noise isremoved and the decision variables are optimized to reach the objective,there is no noise and a high visual display quality results. Thesegmented silhouette 64 matches very closely to the line-up silhouetteafter the photometric calibration 14 process. The photometriccalibration 14 process includes attaching a score to the measureddifferences between the many x,y coordinates of line-up silhouette 60and the segmented silhouette 64. Any pixel coordinates that aredifferent are counted as a point. A given configuration of the decisionvariables results in the score. The objective is to find the set ofparameters or decision variable assignments that result in the lowestscore. The lower the resultant score, the closer the segmentedsilhouette 64 is to the line-up silhouette 60. Once they are matching,the interactive imaging system is calibrated.

A contribution of this system and method is to use a second camera, avisible pass filtered camera, to automatically estimate cameracoordinates. This system and method combines the automaticprojector-camera and homography estimation method of R. Sukthankar, R.Stockton, M. Mullin. Smarter Presentations: Exploiting Homography inCamera-Projector Systems. Proceedings of International Conference onComputer Vision, 2001 and the automatic camera-camera homographyestimation method of M. Brown and D. G. Lowe. Recognising Panoramas. InProceedings of the 9th International Conference on Computer Vision(ICCV2003), pages 1218-1225, Nice, France, October 2003.

A homography is a 2D perspective transformation, represented by a 3×3matrix, that maps each pixel on a plane such as a camera's image planeto another plane, such as a projector's image plane, through anintermediate plane, such as the display surface. By computing ahomography between two planes, we may look up the corresponding pixellocations between the two planes. A camera-projector homography, forexample, would enable the determination of the location of a projector'scorner (such as the origin coordinate at x=0, y=0) to the same locationin the camera (such as x=13, y=47). By estimating theprojector<->visible_camera homography and estimating theIR_camera<->visible camera homography, one may find corresponding pixellocations between the projector and IR-pass camera. This enables theautomatic determination of warping parameters C₁, C₂, C₃, C₄.

During segmentation runtime, each camera snapshot F is subtracted fromthe background model and the resulting difference image D=F−B is furtherprocessed to generate a binary segmentation output. A threshold variablet is used to evaluate D according to the following: Ifabsolute_value(D)>t, output a white pixel denoting foreground, elseoutput a black pixel denoting background. This result of this thresholdoperation, S, may be immediately used as a segmentation as it is abinary image with a (probably noisy) representation of the foreground.Following the threshold operation, a median filter is performed toeliminate small foreground connected components which may result fromnoise or error in the threshold setting. The number of median filteroperations n and size of the median filter kernel m may be tuned toproduce different results. Furthermore, the camera's exposure e may bechanged to produce darker images if the image is overexposed andbrighter images if underexposed.

The background subtraction technique for generating segmentation imagesrequires setting the following parameters: C₁, C₂, C₃, C₄ , t, m, n ande. C₁, C₂, C₃, C₄ are parameters for geometric calibration and t, m, nand e are photometric calibration parameters. The disclosed method iscapable of automatically tuning these parameters by optimizing anobjective function. The objective function evaluates the differencebetween the segmentation algorithm computed with given assigned valuesof the parameters or decision variables and ground truth or model of anexpected segmentation for a given human configuration. The only input onthe part of the user or operator is to stand in a fixed location witharms outspread, or another easily attainable, simple stationary pose.

The objective function that is optimized includes gradient descent (seeEric W. Weisstein. “Method of Steepest Descent.” From Math World—AWolfram Web Resource.http://mathworld.wolfram.com/MethodofSteepestDescent.html),Levenberg-Marquardt, (see Eric W. Weisstein. “Levenberg-MarquardtMethod.” From Math World—A Wolfram Web Resource.http://mathworld.wolfram.com/Levenberg-MarquardtMethod.html), and thelike. Each is an optimization technique of applied mathematics and iswell-known in the art.

In a preferred embodiment of the invention, the interactive imagingsystem 10 is set-up in an appropriate location and powered on. The imagegenerator 20 projects a calibration image, a line-up silhouette 62, ontoa display medium 30. As an interactive imaging system 10 user stands ata fixed location between the image generator 20 and the display medium30, the actual body 62 presence is detected by both the visible imagesensor 22 and the infrared image sensor 24.

Depending on which calibration method is used and depending on whichsegmentation algorithmic is used, various parameters will be set andinitialized, and then optimized in an objective function. Theseparameter values, once initialized, are used in various segmentationalgorithms. Calibration methods include, but are not limited to,geometric calibration 12 and photometric calibration 14. Segmentationalgorithms or techniques include, but are not limited to, backgroundsubtraction and stereo disparity-based foreground detection.

For example, if geometric calibration and background subtraction arechosen, the parameters to be optimized are C₁, C₂, C₃, and C₄, thewarping parameters, which are coordinates in a camera image. In such anexample, the infrared image sensor 42 and the visible image sensor 52are both viewing the display medium 30 and actual body 62 duringcalibration. Features visible in the infrared image sensor 42 andfeatures visible in the visible image sensor 52 allow for a mapping fromthe infrared image sensor 24 to the visible image sensor 22. Mapping 1,IR-to-VIZ, 70 illustrates an infrared-to-visible homography. Theinfrared image sensor 24 is unable to view the image generator 20;however, the visible image sensor 22 is able to view the image generator20. The ability to view the image generator 20 in the visible imagesensor 22 allows a mapping to be made between the visible image sensor22 to the image generator 20. Mapping 2, VIZ-to-PROJ, 72 illustrates avisible-to-projector homography. Mapping, 3 IR-to-PROJ, 74 illustratesthe multiplication of the results of mapping 2, VIZ-to-PROJ, 72multiplied against the results of the mapping 1, IR-to-VIZ, 70. Mapping3, IR-to-PROJ, 74 is a mapping from the infrared image sensor 24 to theimage generator 20.

The coordinates in the camera image, C₁, C₂, C₃, C₄ are the parametersfor geometric calibration. As the parameter values are changed, variousresults are produced. By estimating the VIZ-to-PROJ homography andestimating the IR-to-VIZ homography, one may find corresponding pixellocations between the image generator 20 and the infrared image sensor24. This enables the automatic determination of warping parameters C₁,C₂, C₃, C₄.

By incorporating the use of an objective function, the differencesbetween the segmentation algorithm, computed with given assigned valuesof the parameters or decision variables, and ground truth, or model ofan expected segmentation for a given actual body 62 configuration, areevaluated. This in effect mathematically determines the correctness orgoodness of a parameter value. With the rapid optimization of anobjective function, good parameter values can be quickly set and thesegmented silhouette 64, with no noise and with a high visual quality isreached, thus calibrating the interactive imaging system 10.

Although the present invention has been illustrated and described withreference to preferred embodiments and examples thereof, it will bereadily apparent to those of ordinary skill in the art that otherembodiments and examples may perform similar functions and/or achievesimilar results. All such equivalent embodiments and examples are withinthe spirit and scope of the invention and are intended to be covered bythe following claims.

1-23. (canceled)
 24. A system, comprising: an infrared image sensorconfigured to detect infrared illumination energy in a field of view; alight sensor configured to detect visible light in the field of view;and a control unit communicatively coupled to the infrared image sensorand the light sensor, wherein the control unit is configured to: detectinteractions between a user and a display medium and create audio/visualsignals in response; modify the audio/visual signals in response to thepresence and/or motion of the user, thereby providing user interactionin a virtual environment; and use the light sensor to capture an imageof the user or other calibration object and display or project the imageon the display medium.
 25. The system of claim 24, wherein the controlunit is configured to: calibrate the infrared image sensor and/or thelight sensor using a segmentation algorithm with a plurality ofparameters and an objective function to set and optimize the pluralityof parameters of the segmentation algorithm.
 26. The system of claim 24,further comprising: one or more illumination energy devices configuredto flood the field of view in front of the projected image withillumination energy for detection by the infrared image sensor.
 27. Thesystem of claim 24, wherein the segmentation algorithm is backgroundsubtraction.
 28. The system of claim 24, wherein the segmentationalgorithm is stereo disparity-based foreground detection.
 29. The systemof claim 25, wherein the objective function comprises a gradient descentmethod.
 30. The system of claim 25, wherein the objective functioncomprises a Levenberg-Marquardt method.
 31. The system of claim 24,wherein the control unit is configured to: detect the user with both theinfrared image sensor and the light sensor.
 32. The system of claim 24,wherein the control unit is configured to: display an image of the useron the display medium.
 33. A control unit, comprising: connections to aninfrared image sensor configured to detect infrared illumination energyin a field of view and a light sensor configured to detect visible lightin the field of view; a computer vision engine configured to display orproject on a display medium a image of a user captured by the lightsensor; a computer interaction engine configured to detect interactionsbetween the user and images on the display medium and createaudio/visual signals in response; and a computer rendering engineconfigured to modify the audio/visual signals in response to thepresence and/or motion of the user, thereby providing user interactionin a virtual environment.
 34. The control unit of claim 33, wherein thecomputer vision engine is configured to: calibrate the infrared imagesensor and/or the light sensor using a segmentation algorithm with aplurality of parameters and an objective function to set and optimizethe plurality of parameters of the segmentation algorithm.
 35. Thecontrol unit of claim 33, wherein the connections further connect to oneor more illumination energy devices configured to flood the field ofview in front of the projected image with illumination energy fordetection by the infrared image sensor.
 36. The control unit of claim33, wherein the segmentation algorithm is background subtraction. 37.The control unit of claim 33, wherein the segmentation algorithm isstereo disparity-based foreground detection.
 38. The control unit ofclaim 34, wherein the objective function comprises a gradient descentmethod.
 39. The control unit of claim 34, wherein the objective functioncomprises a Levenberg-Marquardt method.
 40. The control unit of claim33, wherein the control unit is configured to: detect the user with boththe infrared image sensor and the light sensor.
 41. The control unit ofclaim 33, wherein the control unit is configured to: display an image ofthe user on the display medium.
 42. A method, comprising: providing aninfrared image sensor configured to detect infrared illumination energyin a field of view, a light sensor configured to detect visible light inthe field of view, and a control unit communicatively coupled to theinfrared image sensor and the light sensor; detecting interactionsbetween a user and a display medium and create audio/visual signals inresponse; modifying the audio/visual signals in response to the presenceand/or motion of the user, thereby providing user interaction in avirtual environment; and using the light sensor to capture an image ofthe user and displaying or projecting the image on the display medium.